Litcius/Paper detail

High-performance silicon photonic single-sideband modulators for cold-atom interferometry

Ashok Kodigala, Michael Gehl, Gregory W. Hoth, Jongmin Lee, Christopher T. DeRose, Andrew Pomerene, Christina Dallo, Douglas C. Trotter, Andrew Starbuck, Grant Biedermann, Peter Schwindt, Anthony L. Lentine

2024Science Advances27 citationsDOIOpen Access PDF

Abstract

The laser system is the most complex component of a light-pulse atom interferometer (LPAI), controlling frequencies and intensities of multiple laser beams to configure quantum gravity and inertial sensors. Its main functions include cold-atom generation, state preparation, state-selective detection, and generating a coherent two-photon process for the light-pulse sequence. To achieve substantial miniaturization and ruggedization, we integrate key laser system functions onto a photonic integrated circuit. Our study focuses on a high-performance silicon photonic suppressed-carrier single-sideband (SC-SSB) modulator at 1560 nanometers, capable of dynamic frequency shifting within the LPAI. By independently controlling radio frequency (RF) channels, we achieve 30-decibel carrier suppression and unprecedented 47.8-decibel sideband suppression at peak conversion efficiency of −6.846 decibels (20.7%). We investigate imbalances in both amplitudes and phases between the RF signals. Using this modulator, we demonstrate cold-atom generation, state-selective detection, and atom interferometer fringes to estimate gravitational acceleration, g ≈ 9.77 ± 0.01 meters per second squared, in a rubidium ( 87 Rb) atom system.

Topics & Concepts

SidebandPhotonicsInterferometrySiliconCompatible sideband transmissionAtom (system on chip)OptoelectronicsSilicon photonicsUltracold atomMaterials scienceOpticsPhysicsTelecommunicationsComputer scienceMicrowaveQuantum mechanicsEmbedded systemQuantumAdvanced Fiber Laser TechnologiesAtomic and Subatomic Physics ResearchQuantum optics and atomic interactions